EU:n haut ja rahoitusinstrumentit Elina Holmberg, Tekes EVE Business Breakfast, 30.9.2015
Miten EU toimii? EU:n budjetti Hallinnoidaan Suomesta: mm. rakennerahastot, maatalouden tuki ym. Hallinnoidaan Euroopan komissiosta: mm. Horisontti 2020
Rahoitusta tutkimukseen ja innovointiin Rahoitus perustuu kilpailuun: vain parhaat hanke-ehdotukset rahoitetaan. Eurooppa nousuun kasvua, kilpailukykyä, työllisyyttä. EU2020-kasvustrategia Innovaatiounioni-hanke Hakemukset lähetetään Euroopan komissioon Brysseliin, jossa ulkopuoliset asiantuntijat arvioivat ne. Horisontti 2020 ohjelma on Euroopan unionin tärkein väline, jolla rahoituksen avulla ohjataan innovointia ja tutkimusta.
Horisontti 2020
Horisontti 2020 - Rakenne I Huipputason tiede II Teollisuuden johtoasema III Yhteiskunnalliset haasteet 1. Euroopan tutkimus-neuvosto (ERC): tutkimus tieteen eturintamassa 2. Tulevat ja kehittyvät teknologiat (FET) a) avoimet b) ennakoivat c) lippulaivatoimet 3. Marie Skłodowska-Curie (MSCA) toimet: tutkijaliikkuvuus 4. Tutkimusinfrastruktuuri 1. Johtoasema mahdollistavilla ja teollisuusteknologioilla 1.1. tieto- ja viestintäteknologia 1.2. nanoteknologiat 1.3. kehittyneet materiaalit 1.4. bioteknologia 1.5. kehittynyt valmistus ja prosessointi 1.6. avaruus 2. Riskirahoituksen saatavuus: laina & pääoma 3. Innovointi pk-yrityksissä 20% II + III-pilarien rahoituksesta pk-yrityksille - Pk-instrumentin kautta (1/3) - Normaalit yhteisprojektit (2/3) 1. Terveys, väestönmuutos ja hyvinvointi 2. Elintarviketurva, kestävä maa- ja metsätalous, merien ja merenkulun sekä sisävesien tutkimus ja biotalous 3. Turvallinen, puhdas ja tehokas energia 4. Älykäs, ympäristöystävällinen ja yhdentynyt liikenne 5. Ilmastotoimet, resurssitehokkuus ja raaka-aineet 6. Eurooppa muuttuvassa maailmassa: osallistavat, innovatiiviset ja pohtivat yhteiskunnat 7. Turvalliset yhteiskunnat: Euroopan ja sen kansalaisten vapauden ja turvallisuuden suojeleminen Lisäksi osiot Huippuosaamisen levittäminen ja osallistujapohjan laajentaminen sekä Tiede yhteiskunnassa, yhteiskuntaa varten Yhteinen tutkimuskeskus JRC Euroopan innovaatio- ja teknologiainstituutti EIT Ydinenergia-alan EURATOM-ohjelma
Osallistujat Pääsääntöisesti yhdessä! Joissain rahoitusmuodoissa yksi osallistuja riittää Minimivaatimus yhteistyöprojektissa: Kolme osallistujaa kolmesta eri EU- tai liitännäisvaltiosta Pk-instrumentti ERC-rahoitus, ohjelmien yhteisrahoitustoimet Ana R. Madridin kaupunki Gunilla P. Volvo Buses Konsortio Erkki N. Oulun yliopisto Kaikki ovat toisistaan riippumattomia Tutkijoiden, T&I-henkilöstön koulutus ja liikkuvuus Koordinointi- ja tukitoimet
Avustus Innovaatiohankkeet 70 % välittömistä kuluista (non-profit tässäkin 100 %) Tutkimushankkeet 100 % välittömistä kuluista + 25% (välillisten kulujen kattamiseksi) Ennakkomaksukäytäntö
Innovaatiotaso & rahoitus Technology Readiness Level 100% rahoitus. 70% rahoitus. SME Instrument, TRL 6 Funding rate 70% (poikkeus: Health) 1 2 3 4 5 6 7 8 9 Basic principles observed Concept Formulized Proof of Concept Validation in lab Technical validation in relevant environment Demonstration in relevant environment Demo in operational environment System complete and operational Commercial H2020-rahoituksen erot Tekes-rahoitukseen verrattuna: 1. Rahoitusta markkinaläheisempiin projekteihin 2. Korkeampi rahoitusprosentti, organisaatiotyypistä riippumatta 3. Ennakkomaksu
Green Vehicles haut Liikenne-työohjelmassa 2016-17: GV-01-2017. GV-02-2016. GV-03-2016. GV-04-2017. GV-05-2017. GV-06-2017. GV-07-2017. GV-08-2017. GV-09-2017. GV-10-2017. GV-11-2016. (GV-12-2016. Optimisation of heavy duty vehicles for alternative fuels use (IA) Technologies for low emission light duty powertrains (RIA) System and cost optimised hybridisation of road vehicles (IA) Next generation electric drivetrains for fully electric vehicles, focusing on high efficiency and low cost (RIA) Electric vehicle user-centric design for optimised energy efficiency (RIA) Physical integration of hybrid and electric vehicle batteries at pack level aiming at increased energy density and efficiency (IA) Multi-level modelling and testing of electric vehicles and their components (RIA) Electrified urban commercial vehicles integration with fast charging infrastructure (IA) Aerodynamic and flexible trucks (IA) Demonstration (pilots) for integration of electrified L-category vehicles in the urban transport system (IA) Stimulating European research and development for the implementation of future road transport technologies ERA-NET Co-fund on electromobility)
Topics Single stage GV-02, GV-03, GV-11, GV-12 26/01/2016 at 17.00.00 Brussels time Single stage GV-01, GV-04, GV-05, GV-06, G-07, GV-08, GV-09, GV-10 02/02/2017 at 17.00.00 Brussels time
GV-01-2017. Optimisation of heavy duty vehicles for alternative fuels use (IA) Scope: Proposals should focus on one or several of the following fuel options: Bio-methane mixed into liquefied natural gas: LNG is an attractive option to mitigate the high dependence of HDV on diesel. However, to achieve a significant level of GHG emission reduction, it is essential to shift from natural gas to bio-methane. Proposals should consider the results of the LNG Blue Corridors projects and other projects funded by the EU under the European Green Vehicles Initiative. Biofuels ED95 and B30: the use of E95 (95 % ethanol and 5% ignition improver) and B30 (30% Biodiesel and 70% of diesel) for HDV could reduce the EU dependence on diesel. E95 has been already been demonstrated in urban fleets but could be an appropriate fuel for trucks running over short and medium distances. Proposals should contribute to the transition from the 1st to the 2nd generation of such biofuels.
GV-02-2016. Technologies for low emission light duty powertrains (RIA) Scope: Proposals should address one of the following domains: New generation of non-hybrid engines based on existing engine technologies (short term developments): proposals will address the optimal combination of innovative engine and robust after-treatment technologies as well as modelling and testing to improve the design and control capability. Future combustion engines for electrified powertrains (longer term developments): new combustion processes, sensing, control and after treatment systems, supported by advanced modelling technologies where needed to allow these engines to meet future ambitious energy and emission targets simultaneously.
GV-03-2016. System and cost optimised hybridisation of road vehicles (IA) Scope: Proposals should address all the following aspects in light-duty and/or heavy-duty vehicles: For range extended electric vehicles, development of novel high efficiency and high power density energy generators and close integration with electric systems. For pure and plug-in hybrids, power-train system integration and optimisation through the re-use of waste heat, advanced control, downsizing of ICEs, innovative transmissions and the integration of high temperature electronic components.
GV-04-2017. Next generation electric drivetrains for fully electric vehicles, focusing on high efficiency and low cost (RIA) Scope: Proposals should address one or several of the following aspects: Functional system integration of electric machines (e.g. high speed motors) with transmissions, optimisation of energy recovery with the integration of braking systems. Lower cost electric machines through reduced need for rare earth magnets and designs optimised for lower cost manufacturing processes. Integration of power electronics with battery charging functions together with associated control and of wide bandgap semiconductors providing high temperature, high power density, and high frequency capabilities. Modular electric power train components compatible with both full electric and hybrid applications, sub-systems and topologies with enhanced NVH, reliability, safety and fault tolerance and robustness, fit for mass manufacturing.
GV-05-2017. Electric vehicle user-centric design for optimised energy efficiency (RIA) Scope: Proposals should address all the following aspects: Analysis of all aspects of the user-centric design of vehicles which directly or indirectly impact energy consumption in a significant way (including visibility, thermal comfort, HMI, ergonomics, postural comfort, noise and vibration, etc.) that may require the development of new methodologies and design tools. Consideration should be taken of gender aspects and other demographic factors such as ageing. Development of solutions, including the application of novel materials, to improve the thermal insulation of vehicles and hence reduce the energy consumption needs over a wide range of ambient conditions. Integration of advanced systems and components, and their control, considering also preconditioning, in order to optimise occupant comfort and well-being with respect to energy consumption. Reducing the weight and thermal inertia of systems and components (including the windshield and window, seats, dashboard, trim, etc.) in the vehicle in order to improve efficiency without reducing performance. Implementation and testing of the different solutions at the full vehicle level in order to ensure that the safety (including during and after crash) and perception of comfort and well-being remain uncompromised.
GV-06-2017. Physical integration of hybrid and electric vehicle batteries at pack level aiming at increased energy density and efficiency (IA) Scope: Proposals should address all the following aspects: Thermal, electrical and mechanical design of battery systems based on lithium and post lithium cells (if available on the market, excluding electrochemistry work) aiming at highly increased energy density and modularity. Design for manufacturing, recycling and second use. Prototyping and mass-production technologies for battery systems. Demonstration of performance, lifetime and safety behaviour including bench testing and demonstration under real life conditions in vehicles.
GV-07-2017. Multi-level modelling and testing of electric vehicles and their components (RIA) Scope: Proposals should address one or several of the following aspects: Investigations on scalable real-time models for e-drive components (e-motor, batteries, inverters, fuel-cell, etc. ) that seamlessly can be used for design, simulation, diagnosis and testing based on existing models and corresponding test and modelling procedures to automatically identify parameters of these models. Development of heterogeneous testing facility for electric traction drive and storage system that enable the functional optimisation, testing and diagnosis of new e-drive concepts at higher frequencies and voltages. Development of systems and methods to assess reliability, energy content and commercial certainty for battery systems at all levels of technology, from cell via packs, vehicles to recycling. Investigation on reliable and automated methods and procedures for parameter identification of physical and/or empiric models of batteries (state of charge and health, lifetime, etc.). Potential for international cooperation in establishing standard procedures should be explored. New tools and methods integrated with control development for improving safety analysis and reducing costs.
GV-08-2017. Electrified urban commercial vehicles integration with fast charging infrastructure (IA) Scope: Actions should address the development of vehicle drive train concepts and energy storage (battery and super-capacitor) which can deliver the required vehicle performance and are able to operate in a pure electric mode with high energy recovery capacity. This will ensure zero emissions and low noise pollution either on the whole mission or in designated low-emission zones, while permitting in the second case highly efficient, low environmental impact internal combustion engine operation without range restrictions in other areas. Such technologies can be applied to one or both of the following vehicle types: Electrified medium duty trucks for urban and peri-urban applications (freight delivery, refuse collection, etc.) capable of time efficient operation. Electrified high capacity (at least 12 m) buses for urban use, capable of following normal timetables and when needed to effectively charge and drive at bus stops with multiple bus lines.
GV-09-2017. Aerodynamic and flexible trucks (IA) Scope: Proposals should address the following aspects: Map, quantify and predict the type of loads carried on roads in Europe and define potential solutions for configurable trucks. Develop new concepts and technologies for trucks with reduced drag, which are safer, comfortable, configurable and cost effective, and ensure satisfaction of different kinds of customer needs and adaptability to actual type of tasks and circumstances. Provide inputs for revising the standardisation and regulatory framework. Demonstrate potential in real time vehicle boundary configuration for best aerodynamics and energy management adapting to the specific load.
GV-10-2017. Demonstration (pilots) for integration of electrified L-category vehicles in the urban transport system (IA) Scope: Proposals should focus on the demonstration of the potential market penetration of EL-Vs in different European cities. It should enable EL-V manufacturers to make vehicles more attractive to the general public, support a mind-shift and encourage the uptake of EL-Vs (in particular two/three wheelers and light quadricycles). The demonstration of EL-Vs as private, shared, or service vehicles will make the public more familiar with easy to operate EL-Vs and allow overcoming issues such as range anxiety. Enabling users to experience the wide range of EL-Vs as part of their daily personal mobility, will make them more aware of their real mobility needs and allow the integration of EL-Vs with other private and public modes of transport. Surveys among private and professional users should measure in how far the demonstration projects provide attractive services and match market demands.
Pk-instrumentti
Pk-instrumentti - Champions League Kansainvälistä kasvua tavoitteleville pk-yrityksille, joilla on korkea kasvu- ja markkinapotentiaali Vain voittoa tavoitteleville pk-yrityksille Aihe vapaa 2. ja 3. pilarin teemoissa Vaihe 1: Kansainvälinen liiketoimintasuunnitelma (konsepti ja toteutettavuus) Vaihe 2: Demonstraatiot, pilotit, markkinareplikaatiot ja innovaatiotoimet. Vaihe 3: yhteydet riskirahoittajiin, nimetty mentori/valmentaja (yht 15 pv) Vain 1 hakemus/yritys kerralla Innovaatio lähellä kaupallistamista Cut-off 4 x vuodessa: maalis-, kesä-, syys- ja marraskuu
Pk-instrumentti Input: Phase 1: Concept and feasibility assessment Idea/Concept : Business Plan I (~10 pages) Activities: Feasibility of concept Risk assessment IP regime Partner search Design study Pilot application intention Output: elaborated Business plan II Lump sum: ~ 50.000 ~ 6 months Phase 2: R&D, demonstration, market replication Input: Business Plan II plus description of activities under Phase II (~30 pages) Activities: Development, prototyping, testing Piloting innovative processes, products and services Miniaturisation/design of products Planning & developing scaling-up (market segments, process etc.) Market replication Output: investor-ready Business plan III Output based payments: 0,5 to 2,5 M EC funding ~12 to 24 months Phase 3: Commercialisation Promote instrument as quality label for successful projects Facilitate access to private finance Support via networking, training, coaching, information, addressing i.a. IP management, knowledge sharing, dissemination SME window in the EU financial facilities (debt facility and equity facility) Connect to measures promoting PCP/PPI No direct funding *5500 projects / 7 years *2500 projects /7 years If 2-3% to Finland 110-165 projects If 2-3% to Finland 50-75 projects
Fast Track to Innovation
FTI innovaatiot markkinoille Rahoitus kaupallistamiseen 70%, 1-3 m Konsortio 3-5 organisaatiota Minimivaatimus yritysosallistumiselle
Kansallinen NCP-yhteyshenkilö apunasi! Elina Holmberg Tekes elina.holmberg@tekes.fi 050 5577 606